Improving Stellar and Planetary Parameters of Transiting Planet Systems: The Case of TrES-2

Abstract

We report on a spectroscopic determination of the atmospheric parameters and chemical abundance of the parent star of the recently discovered transiting planet TrES-2. A detailed LTE analysis of a set of Fe1 and Fe2 lines from our Keck spectra yields Teff = 5850 50 K, g = 4.4 0.1, and [Fe/H] = -0.15 0.10. Several independent checks (e.g., additional spectroscopy, line-depth ratios) confirm the reliability of our spectroscopic Teff estimate. The mass and radius of the star, needed to determine the properties of the planet, are traditionally inferred by comparison with stellar evolution models using Teff and some measure of the stellar luminosity, such as the spectroscopic surface gravity (when a trigonometric parallax is unavailable, as in this case). We apply here a new method in which we use instead of g the normalized separation a/R (related to the stellar density), which can be determined directly from the light curves of transiting planets with much greater precision. With the a/R value from the light curve analysis of Holman et al. holman07b and our Teff estimate we obtain M = 0.9800.062 M and R = 1.000-0.033+0.036 R, and an evolutionary age of 5.1+2.7-2.3 Gyr, in good agreement with other constraints based on the strength of the emission in the Ca2 H & K line cores, the Lithium abundance, and rotation. The new stellar parameters yield improved values for the planetary mass and radius of Mp = 1.198 0.053 MJup and Rp = 1.220+0.045-0.042 RJup, confirming that TrES-2 is the most massive among the currently known nearby (d 300 pc) transiting hot Jupiters. [Abridged]